Blade Insert Illuminator

ABSTRACT

An air gap retractor illumination system includes any suitable retractor such as a McCulloch with a channel in the blade to accommodate an air gap illuminator. The illuminator is preferably made from a suitable light conducting plastic material such as acrylic or polycarbonate or silicone. The illuminator has active portions in which light passes and inactive or dead zones in which light does not pass as a result of the configuration and orientation of the input, output and surfaces of the illuminator. The illuminator is formed to have an air gap surrounding any active portion of the illuminator extending from the light input to the light output portion. The dead zones may include elements to allow the illuminator to securely engage the retractor. The light output portion of the illuminator contains from two to eight output zones, each zone having specially designed output optical structures that control and direct light to escape the illuminator to shine onto a predetermined area of interest or to form one or more predetermined shapes or footprints.

CROSS-REFERENCE

The present application is a continuation of U.S. patent application Ser. No. 16/752,620, filed Jan. 25, 2020, which is a continuation of U.S. patent application Ser. No. 15/968,011, filed May 1, 2018, which is a divisional of U.S. patent application Ser. No. 14/585,403, filed Dec. 30, 2014, now U.S. Pat. No. 9,986,901, which is a continuation of U.S. patent application Ser. No. 14/068,571, filed Oct. 31, 2013, now U.S. Pat. No. 9,468,366, which is a continuation of U.S. patent application Ser. No. 13/300,325 filed Nov. 18, 2011, now U.S. Pat. No. 9,060,707, which is a continuation of U.S. patent application Ser. No. 11/923,483 filed Oct. 24, 2007, now U.S. Pat. No. 8,088,066; the entire contents of which are incorporated herein by reference.

FIELD OF THE INVENTION

The inventions described below relate to the field of medicine and more specifically, to providing in vivo surgical field illumination during surgical procedures.

BACKGROUND OF THE INVENTION

Surgical procedures often employ the use of retractors to separate and hold tissue to expose the underlying tissue on which the procedure is to be performed. Blade retractors are a type of retractor that typically have a flat or slightly curved blade that is inserted into the body. The blade may have a handle portion that is used to manipulate the blade. One or more blade retractors may be used in a surgical procedure. Illumination in these procedures is typically limited to external illumination sources such as ceiling or wall mounted lights or light sources integrated into a headband worn by the surgeon (e.g., LED based or fiber optic based). These light sources provide poor illumination of the deep tissue on which surgery is to be performed. Fiber optic devices may be fixed to a blade retractor to shine light on the deep tissue, but fiber optic systems either provide a small spot of light requiring constant repositioning to view all the tissue, or they provide a very diffuse light that does not adequately illuminate the tissue of interest. The fiber optic also has a very small emission area. Any debris or blood that covers it will block the majority of illumination. Furthermore, fiber optic devices are very expensive, requiring specialized cutting, grinding and polishing. Some blade retractors are provided with length-wise channels into which ancillary retracting or illumination devices may be inserted. Blade insert illumination devices are currently limited to fiber optic approaches with their poor illumination characteristics.

SUMMARY OF THE INVENTION

A retractor with an air gap illuminator uses any suitable retractor such as McCulloch, and includes a channel in the retractor blade to accommodate the illuminator. The illuminator is preferably made from a suitable light conducting plastic material such as acrylic or polycarbonate or silicone. The illuminator is also formed to have an air gap surrounding any active portion of the illuminator from the light input to the light output portion. The illuminator has active portions in which light passes and inactive or dead zones in which light does not pass as a result of the configuration and orientation of the input, output and surfaces of the illuminator. The dead zones may include elements to allow the illuminator to securely engage the retractor. The illuminator may be characterized as having a light input portion, a light conducting portion and a light output portion.

The light input portion of the illuminator receives light from an external light source. Such a light source may be an external light box, e.g., a xenon light box, to which one end of a fiber optic light guide cable is attached to conduct light to the surgical field. In this instance, the other end of the fiber optic cable would be the source of light for the blade insert illuminator, for example, by employing a mating connector on the illuminator so that it may connect to the fiber optic cable. The light input portion may also include a tab, finger or other projection extending from a dead zone to engage the retractor blade at the top or handle end, the projection may be permanently integrated or temporarily attached.

The light conducting portion of the illuminator typically is responsible for conducting light from the light input section to the light output section. It may be simply a section of optical material designed to support total internal reflection that is integral with the light input and light output portions. Surface treatment, e.g., polishing or reflective coating, and the continuous air gap may be used to support total internal reflection.

The light output portion of the illuminator contains from two to eight output zones of generally similar depth, each zone having specially designed output optical structures that control and direct light to escape the illuminator to shine onto a predetermined area of interest or to have a predetermined shape or footprint. Such structures may be molded or cut into the light output zones.

An air gap retractor illumination system includes any suitable retractor such as a McCulloch with a channel in the blade to accommodate an air gap illuminator. The illuminator is preferably made from a suitable light conducting plastic material such as acrylic or polycarbonate or silicone. The illuminator has active portions in which light passes and inactive or dead zones in which light does not pass as a result of the configuration and orientation of the input, output and surfaces of the illuminator. The illuminator is formed to have an air gap surrounding any active portion of the illuminator extending from the light input to the light output portion. The dead zones may include elements to allow the illuminator to securely engage the retractor. The light output portion of the illuminator contains from two to eight output zones, each zone having specially designed output optical structures that control and direct light to escape the illuminator to shine onto a predetermined area of interest or to form one or more predetermined shapes or footprints.

A blade insert illuminator may comprise one or more illuminator sections designed to engage a mating channel or channels formed in the blade. The illuminator is preferably made from a suitable light conducting plastic material such as acrylic or polycarbonate or silicone. Blade insert illuminators may be characterized by having a light input portion, a light conducting portion and a light output portion. The blade illuminator may be oriented at any suitable position along the retractor blade channel.

The light input portion of a blade insert illuminator receives light from an external light source. Such a light source may be an external light box, e.g., a xenon light box, to which one end of a fiber optic light guide cable is attached to conduct light to the surgical field. In this instance, the other end of the fiber optic cable would be the source of light for the blade insert illuminator, for example, by employing a mating connector on the illuminator so that it may connect to the fiber optic cable. The light input portion may include a short section of a light conducting material, such as for example, a suitable plastic or a fiber optic bundle, that is permanently integrated or temporarily attached.

The light conducting portion of a blade insert illuminator typically is responsible for conducting light from the light input section to the light output section. It may be simply a section of optical material designed to support total internal reflection that is integral with the light input and light output portions. Any suitable surface treatment, such as for example, polishing, reflective coating, anti-reflective (AR) coatings and or dielectric coatings may be used to support total internal reflection.

The light output portion of a blade insert illuminator contains specially designed output optical structures that allow light to be extracted from the illuminator to shine onto a predetermined area of interest. Such structures may be molded into the light output portion or such structures may be applied, for example, as a film.

A blade insert illumination system may consist of a single illuminator that contains the light input, light conducting and light output portions in a simple, single device that acts as a waveguide. Such a system may also be comprised of different sections of illuminator components that attach together to form a complete system. In this case, there may be a light input section designed to receive light from a light source, one or more light conduit sections designed to conduct light from the light input section to a light output section, and a light output section containing the optical output structures that allow light to escape and illuminate a predetermined area of interest, said sections attaching together to form a complete system. Each section acts as a waveguide and may employ optical structures to polarize and or filter the light energy entering or exiting the waveguide.

A blade insert illuminator must be designed and fabricated to maximize light transfer from the light source or fiber optic input cable and minimize light loss from the waveguide in order to provide an efficient light transmission system. Efficiency is particularly important for LED and other light sources, e.g., halogen or xenon lamps, because it directly determines the required brightness of the LED. An inefficient waveguide experiences significant light loss, typically 60% of light may be lost from input to output. Such a light guide would require a high power LED to provide sufficient light. A high power LED requires a lot of power and generates significant heat, thereby requiring large batteries and bulky and inconvenient heat sinking devices and methods that add to the size and increase the difficulty of using such a device. Other high power light sources often require noisy fans, which may disturb the medical personnel conducting a surgery or medical exam. Lamps used in high power light sources have a limited life time, requiring frequent and expensive replacement, due to the need to drive the lamp at high power levels to generate enough light. An efficient waveguide, one in which light loss is typically less than 30%, allows a much lower power LED or other light source to be used, thereby significantly reducing or eliminating the need for special heat sinking devices and methods, reducing cost, and improving the usability of the device. The design of an efficient blade insert illumination waveguide may involve special design of the light input portion of the waveguide to efficiently capture the incoming light, for example, by careful selection of numerical apertures or using a lens, design and fabrication of the light reflecting walls of the light conducting portion of the waveguide to maintain surface finish to maximize reflection and reduce light lost through refraction, the use of reflective or dampening coatings, the design of light directing optical structures that direct the light toward the light output optical structures while minimizing light loss through refraction, and or the design of light output optical structures that maximize light exiting the waveguide through refraction, particularly refraction of light in certain directions, while minimizing light lost through reflection.

A blade insert illumination system includes one or more illumination elements composed of a transparent or semi-transparent polymer that is preferably biocompatible and sterilizable. The illumination elements operate as a waveguide and may incorporate optical components such as, for example, symmetric or asymmetric facets, lenses, gratings, prisms and or diffusers to operate as precision optics for customized delivery of the light energy. The illumination elements may be modular, allowing components to be mixed and matched for different sizes of blade retractors, or may be a single integrated unit. Each module may also have different performance characteristics such as a diffuse light output or a focused light output allowing users to mix and match optical performance as well.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view of a blade insert illuminator.

FIG. 1A is a cross-section of the blade insert illuminator of FIG. 1 taken along A-A.

FIG. 1B is a cross-section of the blade insert illuminator of FIG. 1 taken along B-B.

FIG. 2 is a perspective view of an alternate blade insert illuminator.

FIG. 2A is a perspective view of the attachment mechanism of the blade illuminator of FIG. 2 .

FIG. 3 is a perspective view of another blade insert illuminator.

FIG. 3A is a close perspective view of the light output section of the blade illuminator of FIG. 3 .

FIG. 3B is a close perspective view of a conduit section of the blade illuminator of FIG. 3 .

FIG. 3C is a front view of a light ray path for a light conduit section of the blade illuminator of FIG. 3 .

FIG. 4 is a perspective view of a single waveguide blade illuminator with a flexible input coupling for a short blade retractor.

FIG. 5 is a perspective view of a single waveguide blade illuminator system with a flexible input coupling for a long blade retractor.

FIG. 5A is a perspective view of an alternate waveguide blade illuminator with a rigid input coupling.

FIG. 6 is a perspective view of an alternate attachment mechanism for blade insert illuminator sections.

FIG. 7 is a side view of blade insert illuminator with stepped waveguide sections.

FIG. 8 is a perspective view of an alternate single waveguide blade insert illumination system.

FIG. 9 is a perspective view of a single waveguide blade insert with a light directing structure.

FIG. 10 is a perspective view of a single waveguide blade insert with a light directing structure with an attachment mechanism.

FIG. 11 is a perspective view of a single waveguide blade insert with a waveguide element co-molded with a retracting element.

FIG. 12 is a perspective view of an illuminated retractor.

FIG. 12A is an exploded view of the input collar and the illumination blade input.

FIG. 13 is a cross-section view of the illuminated retractor of FIG. 12 .

FIG. 14 is a side view of the illumination blade of FIG. 12 .

FIG. 15 is a front view of the illumination blade of FIG. 12 .

DETAILED DESCRIPTION OF THE INVENTION

Retractor illumination system 10 of FIG. 1 includes blade retractor 12 including channel 13 to engage a fiber optic input 14 and waveguide illuminator 16. Latch 17 serves to mechanically attach waveguide illuminator 16 to fiber optic input 14 so that the resulting assembly may be moved up and down in channel 13 to any position suitable for illumination. The optical coupling between fiber input 14 and waveguide illuminator 16 is a simple face-to-face coupling, which may be enhanced by use of an index matching gel, or other similar material, applied to either the fiber input 14 or the waveguide illuminator 16 or both. Light entering waveguide illuminator 16 is contained within the waveguide with minimal light loss until it reaches output optical structures such as output structures 18, where light exits to illuminate the predetermined illumination area 20. Output optical structures 18 may include one or more stair stepped facets or lenses that may include a radius or angled face, one or prism structures, one or more diffraction gratings, applied optical film, or other optical structures designed to direct the available light to the predetermined illumination area 20.

In the cross-section view of FIG. 1A channels 13 of blade 12 engage waveguide illuminator 16. Any suitable channel configuration may be used, such as, for example, a single channel with a circular or rhomboid cross-section. The section view of FIG. 1B shows a section of blade retractor 12, waveguide illuminator 16 and fiber input 14, with detail showing latch 17 which snaps into a hole or detent 14D formed in fiber input 14 and the latch may be disengaged with a minor amount of force. Output optical structures 18 control and direct output light energy 21 which illuminates predetermined illumination area 20.

Alternate blade insert illumination system 22 of FIG. 2 includes blade retractor 24 that includes light input section 26, one or more light conduit sections such as light conduit section 27, and a light output section such a light output section 28 that includes one or more output optical elements such as output optical elements 30. In this configuration, light input section 26 has an integrated fiber optic input 32. One or more fiber optic strands such as strands 32A and 32B may be integrated into the upper portion of light input section 26 by molding the strands into light input section 26, gluing the strands into a formed receiving hole 26R formed into the section, or other suitable methods. A light coupling element such as element 33 may also be included to improve light coupling and distribution. A collar such as collar 34 may be provided to aid in strain relief for the optical fiber input. Light directing structure 36 causes the light coming into the center of the waveguide illuminator to be directed along the sides of light input section 26. The same light directing structure is shown in light conduit section 27, serving to direct the light down to the next section. Light input section 26 and light conduit section 27 may be provided without the light directing structure, but this may result in a decrease in efficiency.

Output optical element 30 may have a flat face to which an optical output film is applied to allow light to escape and direct the light toward tissues of interest, or output section 28 may have output optical film or molded structures located on or integrated into rear face 28R that serve to send light out through output optical element 30.

FIG. 2A shows the blade insert illuminator system of FIG. 2 with light conduit section 27 removed to show the section attachment mechanism consisting of one or more male members such as engagement member 38 and a corresponding receptacle such as receptacle 39. Output end 38A of the male member 38 may also include one or more output transmission coupling structures or optical structures, e.g., a lens, such as lens 38L to focus the light into the corresponding receptacle. Bottom 39A of receptacle 39 may also include one or more input transmission coupling structures or optical structures, e.g., a lens, such as lens 39L to spread light into its corresponding waveguide. In use, the male members are pressed into the female receptacles of the subsequent section and friction holds the sections together.

In this configuration, light conduit section 27 of FIG. 2 may be removed, allowing light input section 26 and light output section 28 to be directly connected together, for example, to fit a blade having a short length or to permit adjustment along the blade retractor of the waveguide element to adjust the location of the illumination area. One or more light conduit sections 27 may be added to the assembly to fit blades of medium or long length thereby providing a modular blade insert illumination system whose components may be mixed and matched as needed. For example, if more than one blade retractor is used in a procedure, one blade may be fitted with a shorter assembly of blade illumination components to illuminate the upper part of the surgical field and a second blade may be fitted with a longer assembly of blade illumination system components to illuminate the lower, deeper part of the surgical field. Sliding a blade insert illumination system up and down slightly within the blade channel allows the illumination area to be adjusted, for example, sliding the light output section closer to the work area increases the intensity of illumination and sliding it away from the work area provides a more diffuse, less intense illumination. In this way, the modular blade insert illumination system may be optimized for a particular type of work to be performed.

FIG. 3 illustrates an alternate blade insert illumination system 40 inserted into blade 12. Blade insert illumination system 40 includes light input section 40A, one or more light conduit sections such as conduit sections 40B and light output section 40C. Bifurcated fiber optic cable 41 is integrated into light input section 40A. This blade illuminator configuration includes an engagement arm 42 and light directing structure 44.

FIGS. 3A, 3B and 3C illustrate details of arm 42 and light directing structure 44. When two or more modular elements of blade insert illuminator system 40 engage channels 13, the engagement arm 42 of first element 40B engages adjacent element 40A to maintain a secure optical connection at interface 45 between the elements. Arm 42 is a generally resilient member to permit flexing at joint 46 which permits tooth 47 to engage the light directing structure of the adjacent element. One or more light control elements such as light collecting lens 48 may be included at the input end of each blade illuminator element such as input end 49 of light output section 40C. Similarly, light output lens 50 may be included at the bottom, exit or output end 51 of a light conduit section such as conduit section 40B. Lenses 48 and 50 are illustrative of the use of optical structures to aid in the transmission of light between modules. Any other suitable optical structures such as angled facets, multi-faceted lens structures, spherical or aspherical lens may also be used. FIG. 3C illustrates how light travels in a blade insert illuminator conduit such as conduit element 40B. Light from bifurcated fiber optic cable 41 first enters the top of light input section 40A as illustrated in FIG. 3 . Light energy 52 entering a blade illuminator waveguide such as conduit 40B, either from the fiber optic cable or light collecting lens 48, are guided by light directing structure 44 and light output lens 50.

Single element blade illuminator 54 is shown in FIG. 4 . In this example, retractor 56 has a short blade 57. When used with a retractor having a long blade, single element blade illuminator 54 may be adjusted along the length of the retractor blade to provide illumination wherever it is needed.

In this configuration, a short section of fiber optic cable 58 is integrated into blade illuminator waveguide 60 at the output end and has any suitable connector 62 such as an industry standard ACMI connector or any other type of standard or proprietary connector, at the input end. Connector 62 is normally connected to a standard fiber optic light guide cable that conducts light from an external light source. Since blade insert illumination system 54 is made to minimize light loss, portable LED light sources 62 a may be attached directly to connector 62 or via a much shorter fiber optic light guide cable. Short section of fiber optic cable 58 is flexible and allows considerable latitude in how the connector 62 and light guide cable are oriented. For example, the connector 62 may be placed toward handle 56H of retractor 56 or it may be placed on either side in order to keep out of the way of the surgeon and any other equipment that may be in use.

Single element extended blade illuminator system 64 of FIG. 5 is a simple blade insert illuminator designed to fit long blade retractors such a retractor 66. Illuminator waveguide 68 receives light at input 69, conducts light through total internal reflection throughout center portion 68C, and output optical structures such as output structure 70 directs the light toward a predetermined area to be illuminated.

FIGS. 4 and 5 illustrate that a blade insert illuminator may be provided in different sizes appropriate for the size of the retractor blade with which it is to be used. Blade insert illuminator 72 of FIG. 5A is an extended waveguide blade illuminator with a rigid light input component 73 in the place of the short section of fiber optic cable 58 as shown in FIGS. 4 and 5 . Rigid light input component 73 allows all of the light guiding sections, waveguide 74 and rigid light input component 73, to be molded as one device, thereby reducing cost of the assembly. Support gussets or flanges such as flanges 75 may be added to provide stability. Flanges 75 may have a coating or film applied to prevent light from escaping or may be made from a different material, for example, using a co-molding or overmolding process. Rigid light input component 73 may have an orthogonal input as shown, requiring light directing structure 76 to direct light from connector 62 down to waveguide 74 of the waveguide illuminator. Rigid light input component 73 may also be formed with a radius, as shown in FIG. 5 , and using total internal reflection to guide the light from connector 62 to the body of the waveguide. Rigid light input component 73 may also be made rotatable, thereby allowing the fiber optic light guide cable to be positioned as needed around the surgical field to avoid interference with other instruments.

FIG. 6 illustrates alternate modular blade insert illuminator elements 80A and 80B showing an alternative placement of latches 82 that hold the waveguide components together. Keeping the latches off to the side of the components, rather than in front as shown in FIG. 3 , reduces the likelihood of the latches being accidentally disengaged or broken by surgical instruments during the course of a surgical procedure. Any other suitable mechanisms may be used to attach the modular components to each other, e.g., dovetail joints, tongue-and-groove joints, adhesives that are preferably index matching adhesives, etc., to optimize light coupling from one module to the next. The attachment mechanisms may also be separate from the optical path, for example, metal pins and sockets may be located in optically inactive areas of the modules.

FIG. 7 is a side view of an alternate modular blade insert illumination system 84 wherein each subsequent waveguide section is lessened in thickness 85. This allows output optical structures such as output structures 86 to be placed at the exposed end of the upstream waveguide, thereby allowing light to be directed from each waveguide section such as sections 84A, 84B, 84C. Each waveguide component such as sections 84A, 84B may have a bottom surface that contains output optical structures 86 over much of its surface to act as a terminal illumination component in case no other subsequent waveguide components are attached. Light output section 84C shows stepped output optical structure 88 on the front side and output optical structures 89 on the back side. Without output optical structures 88 that direct light out of the face, light would be lost out the end of light output section 84C, therefore, the combination of output optical structures 88 and 89 contribute to higher efficiency through less lost light.

Referring now to FIG. 8 , winged blade insert illuminator 90 is shown engaged to retractor 91. Illuminator 90 has integrated wings 92 that may serve an additional retracting function. Wings 92 are oriented generally parallel to long axis 87 of illuminator 90. In this configuration, light is directed to exit output optical structure 94. Light enters illuminator 90 via light input component 95, which may be a fiber optic component or a rigid light conducting component at previously discussed. Because total internal reflection may allow light to enter wings 92, the wings may need a reflective coating to prevent light from exiting the wings and being lost or shining into unwanted directions, such as back into the surgeons eyes.

FIG. 9 illustrates another alternate blade insert illuminator 90A that has a light directing element 96, which serves to direct the light coming into the middle of the illuminator out toward the wings 92A. Output optical structures such as structures 97 and 98 may be placed on wings 92A and body respectively to provide illumination from both structures as shown by the arrows.

FIG. 10 illustrates another alternate blade insert illuminator 90B with an extended light directing element 96B. In this embodiment, optical output structures are placed only on the wings 92B so that illumination, light energy 99, only exits through extended output structures 97B in wings 92B as shown by the arrows. Extended light directing element 96B has reflective walls such as wall 93 that extend to output end 90E of illuminator 90B to maximize light reflected to the wings 92B. This configuration also includes alternative latch arm 100 oriented near the interface with retractor 102 to engage cutouts or detents such as detents 103A, 103B and 103C located in retractor 102. Latch arm 100 maybe made of the same material as the waveguide or may be made of a different material for durability. For example, latch arm 100 may be made from steel or titanium and insert molded into illuminator 90B.

Alternatively, a retractor blade may be inserted into one or more slots in the illuminator waveguide to provide rigidity and or to enable cooperation with surgical site retention apparatus.

Co-molded blade insert illuminator 104 of FIG. 11 includes waveguide section 106 has been co-molded or over-molded with wing and body retractor portions 104W and 104B respectively, which are made of a different material. For example, retractor wing and body portions 104W and 104B may be made of a stronger, glass reinforced plastic or steel or titanium for strength while waveguide section 106 is molded from a suitable optical material such as acrylic, polycarbonate, silicone or other similar optical materials.

Illuminated retractor 107 as illustrated in FIG. 12 is composed of retractor blade 108 and illumination blade 109. Retractor blade 108 is shown as a McCulloch style retractor blade for use with a McCulloch retraction system although any suitable retractor and or retraction configuration may be used. Retractor blade 108 includes one or more mechanical connectors such a mechanical connector 108M and neck slot or channel 110 to accommodate neck zone 124 and blade slot 111 to accommodate output blade 125 within retractor blade 108 while maintaining an air gap between active zones of the illumination blade and the retractor. Two or more engagement elements such as blade or plate 112 and tabs 114 secure illumination blade 109 to retractor blade 108. Each tab 114 engages one or more engagement receptacles such as receptacles or recesses 115. Plate 112 is joined to collar 116, and when collar 116 removably engages input dead zone 122D, the collar surrounds illumination blade input 118. The removable engagement of collar 116 to input dead zone 122D also brings plate 112 into contact with end surface 119 of the retractor blade. Collar 116 securely engages dead zone 122D and surrounds cylindrical input zone 120 and forms input air gap 120G. Engagement at dead zones minimizes interference with the light path by engagement elements such a plate 112 and tabs 114. Plate 112 engages end surface 119 and tabs 114 resiliently engage recesses 115 to hold illumination blade 109 fixed to retractor blade 108 without contact between active zones of illumination blade 109 and any part of retractor blade 108.

Illumination blade 109 is configured to form a series of active zones to control and conduct light from illumination blade input 118 of the cylindrical input zone 120 to one or more output zones such as output zones 127 through 131 and output end 133 as illustrated in FIGS. 12, 13, 14 and 15 . Illumination blade 109 also includes one or more dead zones such as zones 122D, 126D and 126E. Dead zones are oriented to minimize light entering the dead zone and thus potentially exiting in an unintended direction. As there is minimal light in or transiting dead zones they are ideal locations for engagement elements to secure the illumination blade to the retractor.

Light is delivered to illumination blade input 118 using any conventional mechanism such as a standard ACMI connector having a 0.5 mm gap between the end of the fiber bundle and illumination blade input 118, which is 4.2 mm diameter to gather the light from a 3.5 mm fiber bundle with 0.5NA. Light incident to illumination blade input 118 enters the illumination blade through generally cylindrical, active input zone 120 and travels through active input transition 122 to a generally rectangular active retractor neck 124 and through output transition 126 to output blade 125 which contains active output zones 127 through 131 and active output end 133. Retractor neck 124 is generally rectangular and is generally square near input transition 122 and the neck configuration varies to a rectangular cross section near output transition 126. Output blade 125 has a generally high aspect ratio rectangular cross-section resulting in a generally wide and thin blade. Each zone is arranged to have an output surface area larger than the input surface area, thereby reducing the temperature per unit output area.

In the illustrated configuration illumination blade 109 includes at least one dead zone, dead zone 122D, generally surrounding input transition 122. One or more dead zones at or near the output of the illumination blade provide locations to for engagement elements such as tabs to permit stable engagement of the illumination blade to the retractor. This stable engagement supports the maintenance of an air gap such as air gap 121 adjacent to all active zones of the illumination blade as illustrated in FIG. 13 . Neck zone 124 ends with dimension 132 adjacent to output transition 126 which extends to dimension 134 at the output zones. The changing dimensions result in dead zones 126D and 126E adjacent to output transition 126. These dead zones are suitable locations for mounting tabs 114 to minimize any effects of the engagement elements on the light path.

To minimize stresses on the light input and or stresses exerted by the light input on the illumination blade, the engagement elements are aligned to form an engagement axis such as engagement axis 136 which is parallel to light input axis 138.

Output zones 127, 128, 129, 130 and 131 have similar configurations with different dimensions. Referring to the detailed view of FIG. 14 , the characteristics of output zone 127 are illustrated. Each output zone is formed of parallel prism shapes with a primary surface or facet such a primary facet 140 with a length 140L and a secondary surface or facet such as secondary facet 142 having a length 142L. The facets are oriented relative to plane 143 which is parallel to and maintained at a thickness or depth 144 from rear surface 145. In the illustrated configuration, all output zones have the same depth 144 from the rear surface.

The primary facets of each output zone are formed at a primary angle 146 from plane 143. Secondary facets such as facet 142 form a secondary angle 147 relative to primary facets such as primary facet 140. In the illustrated configuration, output zone 127 has primary facet 140 with a length 140L of 0.45 mm at primary angle of 27° and secondary facet 142 with a length 142L of 0.23 mm at secondary angle 88° . Output zone 128 has primary facet 140 with a length 140L of 0.55 mm at primary angle of 26° and secondary facet 142 with a length 142L of 0.24 mm at secondary angle 66°. Output zone 129 has primary facet 140 with a length 140L of 0.53 mm at primary angle of 20° and secondary facet 142 with a length 142L of 0.18 mm at secondary angle 72°. Output zone 130 has primary facet 140 with a length 140L of 0.55 mm at primary angle of 26° and secondary facet 142 with a length 142L of 0.24 mm at secondary angle 66°. Output zone 131 has primary facet 140 with a length 140L of 0.54 mm at primary angle of 27° and secondary facet 142 with a length 142L of 0.24 mm at secondary angle 68°.

Output end 133 is the final active zone in the illumination blade and is illustrated in detail in FIG. 14 . Rear reflector 148 forms angle 149 relative to front surface 150. Front surface 150 is parallel to rear surface 145. Terminal facet 151 forms angle 152 relative to front surface 150. In the illustrated configuration, angle 149 is 32° and angle 152 is 95°.

Other suitable configurations of output structures may be adopted in one or more output zones. For example, output zones 127 and 128 might adopt a concave curve down and output zone 129 might remain generally horizontal and output zones 130 and 131 might adopt a concave curve up. Alternatively, the plane at the inside of the output structures, plane 143 might be a spherical section with a large radius of curvature. Plane 143 may also adopt sinusoidal or other complex geometries. The geometries may be applied in both the horizontal and the vertical direction to form compound surfaces.

In other configurations, output zones may provide illumination at two or more levels throughout a surgical site. For example, output zones 127 and 128 might cooperate to illuminate a first surgical area and output zones 129 and 130 may cooperatively illuminate a second surgical area and output zone 131 and output end 133 may illuminate a third surgical area. This configuration eliminates the need to reorient the illumination elements during a surgical procedure.

While the preferred embodiments of the devices and methods have been described in reference to the environment in which they were developed, they are merely illustrative of the principles of the inventions. Other embodiments and configurations may be devised without departing from the spirit of the inventions and the scope of the appended claims. 

1. A method for illuminating a surgical field, comprising: coupling, using a retractor-engagement element, an optical waveguide to a surgical retractor, wherein the retractor-engagement element extends from the optical waveguide, wherein the retractor-engagement element comprises a plate that extends outwardly from the optical waveguide, wherein the optical waveguide comprises: a light input section configured to receive light from a light source, a light transmitting section distal of the light input section and configured to transmit the light distally from the light input section, and a light output section distal of the light transmitting section and configured to output the light from the optical waveguide; and transmitting light from the light source to the light input section, from the light input section to the light transmitting section, from the light transmitting section to the light output section, and from the light output section to the surgical field.
 2. The method of claim 1, wherein a longitudinal axis of the plate extends from the optical waveguide in a direction that is parallel to a direction in which the light output section extends from the light transmitting section.
 3. The method of claim 1, wherein the plate is distal of the light input section.
 4. The method of claim 1, further comprising coupling, using a collar, the light input section of the optical waveguide to the light source, wherein the collar surrounds the light input section of the optical waveguide.
 5. The method of claim 4, wherein an annular air gap is defined between the collar and the light input section of the optical waveguide.
 6. The method of claim 5, wherein the light input section of the optical waveguide has a cylindrical shape, and wherein the light input section of the optical waveguide and the collar are configured such that the annular air gap surrounds the light input section of the optical waveguide.
 7. The method of claim 4, wherein the collar extends proximally from the plate.
 8. The method of claim 1, wherein the retractor-engagement element comprises a tab that is configured to couple to a recess on the surgical retractor.
 9. The method of claim 1, wherein the light transmitting section is curved.
 10. The method of claim 1, further comprising retracting tissue using the surgical retractor while transmitting the light from the light output section to the surgical field.
 11. A method for illuminating a surgical field, comprising: coupling, using a retractor-engagement element, an optical waveguide to a surgical retractor, wherein the retractor-engagement element extends from the optical waveguide, wherein the optical waveguide comprises: a light input section configured to receive light from an a light source, a light transmitting section distal of the light input section and configured to transmit the light distally from the light input section, and a light output section distal of the light transmitting section and configured to output the light from the optical waveguide, wherein the surgical retractor comprises a slot that receives the optical waveguide, wherein the slot defines a recess on a front side of the surgical retractor, wherein a back side of the surgical retractor is opposite the front side and configured to engage tissue, wherein an entirety of the light transmitting section and an entirety of the light output section of the optical waveguide are on the front side when the optical waveguide is coupled to the surgical retractor; and transmitting light from the light source to the light input section, from the light input section to the light transmitting section, from the light transmitting section to the light output section, and from the light output section to the surgical field.
 12. The method of claim 11, wherein the optical waveguide is disposed in the slot of the surgical retractor such that an air gap is defined between a plurality of active zones of the optical waveguide and the surgical retractor, wherein the plurality of active zones transmit the light through the light transmitting section from the light input section to the light output section.
 13. The method of claim 12, wherein the retractor-engagement element comprises a plate that extends outwardly from the optical waveguide.
 14. The method of claim 13, wherein a longitudinal axis of the plate extends from the optical waveguide in a direction that is parallel to a direction in which the light output section extends from the light transmitting section.
 15. The method of claim 13, wherein the plate is distal of the light input section.
 16. The method of claim 11, wherein the retractor-engagement element comprises a tab that is coupled to a recess on the surgical retractor.
 17. The method of claim 11, wherein the light transmitting section is curved, and wherein the slot is curved such that the light transmitting section is received in the slot.
 18. The method of claim 11, further comprising retracting tissue using the back side of the surgical retractor while transmitting the light from the light output section to the surgical field.
 19. A method of making a system for illuminating a surgical field, comprising: forming an optical waveguide, wherein the optical waveguide comprises: a light input section configured to receive light from an illumination element, a light transmitting section distal of the light input section and configured to transmit the light distally from the light input section, and a light output section distal of the light transmitting section and configured to output the light from the optical waveguide; coupling a retractor-engagement element to the optical waveguide, wherein the retractor-engagement element comprises a plate that extends outwardly from the optical waveguide; and coupling a collar to the light input section of the optical waveguide such that the collar surrounds the light input section of the optical waveguide defines that an annular air gap between the collar and the optical waveguide, wherein the retractor-engagement element is configured to couple the optical waveguide to a surgical retractor.
 20. The method of claim 19, wherein forming the optical waveguide comprises forming the light input section, the light transmitting section, and the light output section as a single, monolithic element of optical material. 